Abstract: A select gate of a NAND memory array has a first dielectric layer formed on a semiconductor substrate. A first conductive layer is formed on the first dielectric layer. Conductive spacers are formed on sidewalls of the first conductive layer and are located between an upper surface of the first conductive layer and the first dielectric layer. A second dielectric layer overlies the first conductive layer and the conductive spacers. A second conductive layer is formed on the second dielectric layer. A third conducive layer is formed on the second conductive layer, passes though a portion of the second conductive layer and the second dielectric layer, and contacts the first conductive layer. The third conductive layer electrically connects the first and second conductive layers.

Abstract: Methods and apparatus are provided. A first dielectric plug is formed in a portion of a trench that extends into a substrate of a memory device so that an upper surface of the first dielectric plug is recessed below an upper surface of the substrate. The first dielectric plug has a layer of a first dielectric material and a layer of a second dielectric material formed on the layer of the first dielectric material. A second dielectric plug of a third dielectric material is formed on the upper surface of the first dielectric plug.

Abstract: Apparatus and methods are provided. Floating-gate memory cells and select gates of NAND memory arrays are formed concurrently by anisotropically removing portions of a second conductive layer disposed on a first conductive layer such that remaining portions of the second conductive layer self align with and are disposed on sidewalls of the first conductive layer. The first conductive layer is disposed on a first dielectric layer that is disposed on a substrate. A second dielectric layer is formed overlying the first conductive layer and the remaining portions of the second conductive layer. A third conductive layer is formed on the second dielectric layer. A fourth conductive layer is formed on the third conductive layer. For the select gate, the fourth conductive layer also passes through the third conductive layer and the second dielectric layer to electrically connect the conductive layers.

Abstract: A method includes removing a portion of a substrate to define an isolation trench; forming a first dielectric layer on exposed surfaces of the substrate in the trench; forming a second dielectric layer on at least the first dielectric layer, the second dielectric layer containing a different dielectric material than the first dielectric layer; depositing a third dielectric layer to fill the trench; removing an upper portion of the third dielectric layer from the trench and leaving a lower portion covering a portion of the second dielectric layer; oxidizing the lower portion of the third dielectric layer after removing the upper portion; removing an exposed portion of the second dielectric layer from the trench, thereby exposing a portion of the first dielectric layer; and forming a fourth dielectric layer in the trench covering the exposed portion of the first dielectric layer.

Abstract: A NAND memory array has a select line coupled to each of a plurality of NAND strings of memory cells of the memory array. The select line has a select gate at each intersection of one of the plurality of NAND strings and the select line. The select line further includes first and second conductive layers separated by a dielectric layer, and a contact that extends from a third conductive layer, disposed on the second conductive layer, to the first conductive layer. The contact is formed in a hole that passes through the second conductive layer and the dielectric layer and that terminates at the first conductive layer. The contact electrically connects the first and second conductive layers. The hole can have a slot shape so that the contact spans two or more NAND strings of the plurality of NAND strings.

Abstract: Methods and apparatus are provided. A NAND memory array has a select line coupled to each of a plurality of NAND strings of memory cells of the memory array. The select line has a select gate at each intersection of one of the plurality of NAND strings and the select line. The select line further includes first and second conductive layers separated by a dielectric layer, and a contact that extends from a third conductive layer, disposed on the second conductive layer, to the first conductive layer. The contact is formed in a hole that passes through the second conductive layer and the dielectric layer and that terminates at the first conductive layer. The contact electrically connects the first and second conductive layers. The hole can have a slot shape so that the contact spans two or more NAND strings of the plurality of NAND strings.

Abstract: Methods and apparatus are provided. A NAND memory array has a select line coupled to each of a plurality of NAND strings of memory cells of the memory array. The select line has a select gate at each intersection of one of the plurality of NAND strings and the select line. The select line further includes first and second conductive layers separated by a dielectric layer, and a contact that extends from a third conductive layer, disposed on the second conductive layer, to the first conductive layer. The contact is formed in a hole that passes through the second conductive layer and the dielectric layer and that terminates at the first conductive layer. The contact electrically connects the first and second conductive layers. The hole can have a slot shape so that the contact spans two or more NAND strings of the plurality of NAND strings.

Abstract: Field-effect transistors, select gates, and select lines have first and second conductive layers separated by an interlayer dielectric layer. A conductive strap is disposed on either side of the first and second conductive layers. Each strap electrically interconnects the first and second conductive layers.

Abstract: A semiconductor device includes a metal silicide interconnect structure and a dielectric layer that are located at substantially the same fabrication level. The metal silicide interconnect and dielectric layer may be fabricated by forming an amorphous or polycrystalline silicon layer on a substrate including at least one gate structure, forming a layer of silicon nitride over the silicon layer, removing a portion of the silicon nitride layer, oxidizing the exposed portion of the silicon layer, removing the remaining portion of the silicon nitride layer, optionally removing the oxidized silicon layer, forming a metal layer over the resulting structure, annealing the metal layer in an atmosphere comprising nitrogen, and removing any metal nitride regions. The local metal silicide interconnect structure may overlie the at least one gate structure.

Abstract: In one implementation, a method of forming a field effect transistor includes etching an opening into source/drain area of a semiconductor substrate. The opening has a base comprising semiconductive material. After the etching, insulative material is formed within the opening over the semiconductive material base. The insulative material less than completely fills the opening and has a substantially uniform thickness across the opening. Semiconductive source/drain material is formed within the opening over the insulative material within the opening. A transistor gate is provided operatively proximate the semiconductive source/drain material. Other aspects and implementations are contemplated.

Abstract: In one implementation, a method of forming a field effect transistor includes etching an opening into source/drain area of a semiconductor substrate. The opening has a base comprising semiconductive material. After the etching, insulative material is formed within the opening over the semiconductive material base. The insulative material less than completely fills the opening and has a substantially uniform thickness across the opening. Semiconductive source/drain material is formed within the opening over the insulative material within the opening. A transistor gate is provided operatively proximate the semiconductive source/drain material. Other aspects and implementations are contemplated.

Abstract: In one implementation, a method of forming a field effect transistor includes etching an opening into source/drain area of a semiconductor substrate. The opening has a base comprising semiconductive material. After the etching, insulative material is formed within the opening over the semiconductive material base. The insulative material less than completely fills the opening and has a substantially uniform thickness across the opening. Semiconductive source/drain material is formed within the opening over the insulative material within the opening. A transistor gate is provided operatively proximate the semiconductive source/drain material. Other aspects and implementations are contemplated.

Abstract: In one implementation, a method of forming a field effect transistor includes etching an opening into source/drain area of a semiconductor substrate. The opening has a base comprising semiconductive material. After the etching, insulative material is formed within the opening over the semiconductive material base. The insulative material less than completely fills the opening and has a substantially uniform thickness across the opening. Semiconductive source/drain material is formed within the opening over the insulative material within the opening. A transistor gate is provided operatively proximate the semiconductive source/drain material. Other aspects and implementations are contemplated.

Abstract: Apparatus and methods are provided. Field-effect transistors, select gates, and select lines have first and second conductive layers separated by an interlayer dielectric layer. A coductive strap is disposed on either side of the first and second conductive layers. Each strap electrically interconnects the first and second conductive layers.

Abstract: A BiCMOS integrated circuit is fabricated using a minimum number of wafer processing steps and yet offers the IC circuit designer five (5) different transistor types. These types include P-channel and N-channel MOS transistors and three different bipolar transistors whose emitters are all formed by a different process and all are characterized by different current gains and different breakdown voltages. A differential silicon dioxide/silicon nitride masking technique is used in the IC fabrication process wherein both P-type buried layers (PBL) and N-type buried layers (NBL) are formed in a silicon substrate using a single mask set and further wherein P-type wells and N-type wells are formed above these buried layers in an epitaxial layer, also using a single SiO2/Si3N4 differential mask set. Two of the bipolar transistor emitters are formed by out diffusion from first and second levels of polysilicon, whereas the emitter of the third bipolar transistor is formed by ion implantation doping.

Abstract: Method and apparatus for improving the high current operation of bipolar transistors while minimizing adverse affects on high frequency response are disclosed. A local implant to increase the doping of the collector at the collector to base interface is achieved by the use of an angled ion implant of collector impurities through the emitter opening. The resulting area of increased collector doping is larger than the emitter opening, which minimizes carrier injection from the emitter to the collector, but is smaller than the area of the base.

Abstract: Method and apparatus for improving the high current operation of bipolar transistors while minimizing adverse affects on high frequency response are disclosed. A local implant to increase the doping of the collector at the collector to base interface is achieved by the use of an angled ion implant of collector impurities through the emitter opening. The resulting area of increased collector doping is larger than the emitter opening, which minimizes carrier injection from the emitter to the collector, but is smaller than the area of the base.

Abstract: Method and apparatus for improving the high current operation of bipolar transistors while minimizing adverse affects on high frequency response are disclosed. A local implant to increase the doping of the collector at the collector to base interface is achieved by the use of an angled ion implant of collector impurities through the emitter opening. The resulting area of increased collector doping is larger than the emitter opening, which minimizes carrier injection from the emitter to the collector, but is smaller than the area of the base.

Abstract: A BiCMOS integrated circuit is fabricated using a minimum number of wafer processing steps and yet offers the IC circuit designer five (5) different transistor types. These types include P-channel and N-channel MOS transistors and three different bipolar transistors whose emitters are all formed by a different process and all are characterized by different current gains and different breakdown voltages. A differential silicon dioxide/silicon nitride masking technique is used in the IC fabrication process wherein both P-type buried layers (PBL) and N-type buried layers (NBL) are formed in a silicon substrate using a single mask set and further wherein P-type wells and N-type wells are formed above these buried layers in an epitaxial layer, also using a single SiO2/Si3N4 differential mask set. Two of the bipolar transistor emitters are formed by out diffusion from first and second levels of polysilicon, whereas the emitter of the third bipolar transistor is formed by ion implantation doping.

Abstract: A BiCMOS integrated circuit is fabricated using a minimum number of wafer processing steps and yet offers the IC circuit designer five (5) different transistor types. These types include P-channel and N-channel MOS transistors and three different bipolar transistors whose emitters are all formed by a different process and all are characterized by different current gains and different breakdown voltages. A differential silicon dioxide/silicon nitride masking technique is used in the IC fabrication process wherein both P-type buried layers (PBL) and N-type buried layers (NBL) are formed in a silicon substrate using a single mask set and further wherein P-type wells and N-type wells are formed above these buried layers in an epitaxial layer, also using a single SiO2/Si3N4 differential mask set. Two of the bipolar transistor emitters are formed by out diffusion from first and second levels of polysilicon, whereas the emitter of the third bipolar transistor is formed by ion implantation doping.